Abstract
Agricultural lands in the peri-urban area of New Delhi have been irrigated with treated wastewater from the Keshopur Effluent Irrigation Scheme (KEIS) since 1979. An attempt has been made to study the influence of wastewater irrigation on pH, electrical conductivity, organic carbon, and dynamics of heavy metal concentrations in vadose zone under KEIS. For this study, agricultural lands which have been receiving the sewage irrigation for 20, 10, and 5 years were selected. Adjacent tube well water-irrigated fields were selected and used as reference. Results indicate that there was a significant decrease in soil pH and electrical conductivity (EC) of sewage water-irrigated fields as compared to tube well water-irrigated fields. Organic carbon (OC) content in 20 years sewage-irrigated soil (0–15 cm) increased by 244 % over tube well water-irrigated soil. The increases in organic carbon content for 10 and 5 years sewage-irrigated surface soil (0–15 cm) were 138 and 60 % over tube well water-irrigated soils. The second-order polynomial model suggested that there is a possibility of accumulation of organic carbon in soil due to sewage irrigation at 1.55 t−1 ha−1 year. There was an increase in diethylene triamine pentaacetic acid (DTPA)-extractable Zn content in 20, 10, and 5 years sewage-irrigated soils (0–15 cm) to the extent of 86, 38, and 36 % over tube well water-irrigated soils, respectively, while only 20 years sewage-irrigated soils showed a significant increase in DTPA-extractable Cu (289 %) in surface layer (0–15 cm) over tube well-irrigated soils. In case of Fe, 127, 88, and 76.6 % increases in available Fe content (DTPA-Fe) were recorded under 20, 10, and 5 years sewage-irrigated soils, respectively, over controls. Like Cu, DTPA-extractable Ni also exhibited a significant increase (42.2 %) in 20 years sewage-irrigated soil over tube well-irrigated ones. It appears that due to sewage irrigation particularly in surface soil, DTPA-Mn content either remained same or showed a slight decline as compared to tube well-irrigated soils. The assessment of contamination factor (CF) in respect of total metal content in soil indicated the moderate level of metal contamination even after such long-term of sewage irrigation.
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Abedi-Koupai, J., Moustafazadeh-Fard, B., Afyuni, M., & Bagheri, M. R. (2006). Effect of treated waste water on soil chemical and physical properties in an arid region. Plant Soil and Environment, 52, 335–344.
Abu-Jaber, N., & Ismail, M. (2003). Hydrogeochemical modeling of shallow groundwater in the northern Jordan Valley. Environmental Geology, 44, 391–399.
Azad, A. S., Sekhon, G. S., & Arora, B. R. (1986). Distribution of cadmium, nickel and cobalt in sewage water irrigated soils. Journal of the Indian Society of Soil Science, 34, 619–621.
Bansal, R. L., Nayyar, V. K., & Takkar, P. N. (1992). Accumulation and bioavailability of Zn, Cu, Mn and Fe in soils polluted with industrial waste water. Journal of the Indian Society of Soil Science, 40, 796–799.
Brar, M. S., Mahali, S. S., Singh, A. P., Arora, C. L., & Gill, K. S. (2000). Sewer water irrigation effects on some of the potential toxic trace elements in soil and potato plants in northwestern India. Canadian Journal of Soil Science, 80, 465–471.
Christiansen, T. H. (1977). Irrigation water quality evaluation. Journal of Irrigation and Drainage ASCE, 103, 155–169.
Cromer, R. N., Tompkins, D., Barr, N. J., & Hopkins, P. (1984). Irrigation of monetary pine with wastewater: effect on soil chemistry and groundwater composition. Journal of Environment Quality, 13, 539–542.
Delibacack, S., Okur, B., & Ongun, A. R. (2009). Effect of sewage sludge levels on temporal variation of some soil properties of Typic Xerofluent soil in Menemen Plain, Western Anatolia, Turkey. Environment Monitoring Assessment, 148, 85–95.
Deshmukh, S. K., Singh, A. K., Datta, S. P., & Annapurna, K. (2011). Impact of long-term wastewater application on microbiological properties of vadose zone. Environmental Monitoring and Assessment, 175(1–4), 601–612.
Esteller, M. V., Morell, I., & Almeida, C. (2001). Physico-chemical processes in a vadose zone during the infiltration of treated wastewater used for irrigation: application of the NETPATH model. Environmental Geology, 40, 923–930.
Feign, A., Ravina, I. & Shalhevet, J. (1991). Irrigation with treated sewage effluents: management for environmental protection. Advance in Agricultural Science. Berlin: Springer, 17 p.
Friedel, J. K., Langer, T., Siebe, C., & Stahr, K. (2000). Effects of long-term waste water irrigation on soil organic matter, soil microbial biomass and its activities in central Mexico. Biology and Fertility of Soils, 31, 414–421.
Hakanson, L. (1980). An ecological risk index for aquatic pollution control: a sedimentation approach. Water Resources, 14, 975–1001.
Hassanli, A. M., Javan, M., & Saadat, Y. (2008). Reuse of municipal effluent with the effect on soil properties in semi-arid area. Environmental Monitoring and Assessment, 144, 151–158.
Hough, R. L., Young, S. D., & Crout, N. M. J. (2003). Modelling of Cd, Cu, Ni, Pb and Zn uptake, by winter wheat and forage maize, from a sewage disposal farm. Soil Use and Management, 19, 19–27.
Jeyabahaskaran, K. J., & Shreeramalu, U. S. (1996). Distribution of heavy metals in soils of various sewage farms in Tamil Nadu. Journal of Indian Society of Soil Science, 44, 401–404.
Jopony, M., & Young, S. D. (1994). The solid-solution equilibria of lead and cadmium in polluted soils previously treated with sewage-sludges. Plant and Soil, 132, 179–196.
Kannan, K., & Oblisami, G. (1990). Effect of pulp and paper mill effluent irrigation on carbon-dioxide evolution in soils. Journal of Agronomy and Crop Science, 164, 116–119.
Lal, R., Kimble, J. M., Follet, R. F, & Cole, C. V. (1998). The Potential of Us cropland to sequester carbon and mitigate the greenhouse effect. Sleeping Bear Press Inc., USA.
Lindsay, W. L., & Norvell, W. A. (1978). Development of a DTPA soil test for zinc, iron, manganese and copper. Soil Science Society of America Journal, 42, 421–428.
Liu, W., Zhao, J., Ouyang, Z., Soderlund, L., & Guo-hua, L. (2005). Impact of sewage irrigation on heavy metal distribution and contamination in Beijing, China. Environment International, 31, 805–812.
Ma, Q., & Lindsay, W. L. (1993). Measurements of free Zn2+ activity in uncontaminated and contaminated soils using chelation. Soil Science Society of America Journal, 57, 963–967.
Masto RE, Chhonkar PK, Singh Dhyan, Patra AK (2008) Environ changes in soil quality indicators under long-term sewage irrigation in a sub-tropical environment. Environment Geology.
Mitra, A., & Gupta, S. K. (1999). Effect of sewage water irrigation on essential plant nutrient and pollutant element status in a vegetable growing area around Calcutta. Journal of Indian Society of Soils Science, 47, 99–105.
Narwal, R. P., Gupta, A. P., Singh, A., & Karwasra, S. P. S. (1990). Pollution potential of some sewage waters of Haryana. In Recent advances in environmental pollution and management. Hisar: Haryana Agricultural University.
Nashikkar, V. J. (1993). Effect of reuse of high BOD wastewaters for crop irrigation on soil nitrification. Environment International, 19, 63–69.
Pescod, M. B. (1992). Wastewater treatment and use in agriculture. FAO irrigation and drainage paper 47. FAO: Rome, 125 p.
Qian, Y. L., & Mecham, B. (2005). Long-term effects of recycled waste water irrigation on soil chemical properties on golf course fairways. Journal of Agronomy, 97, 717–721.
Quevauviller, P. H. (1998). Operationally defined extraction procedures for soil and sediment analysis I. Standardization. Trends in Analytical Chemistry, 17, 289–298.
Rattan, R. K., Datta, S. P., Chhonkar, P. K., Suribabu, K., & Singh, A. K. (2005). Long-term impact of irrigation with sewage effluents on heavy metal content in soils, crops and groundwater—a case study. Agricultural Ecosystem and Environment, 109, 310–322.
Sakal, R., Prasad, A. K., & Singh, A. P. (1992). Journal of Indian Society of Soil Science, 40, 732.
Singh, S. P., & Verloo, M. G. (1996). Accumulation and bioavailability of metals in semi-arid soils irrigated with sewage effluent. Meded Fac Landbouwkd Toegep Wet University Ghent, 61, 63–67.
Snedecor, G. W., & Cochran, W. (1967). Statistical methods (6th ed.). Ames: Iowa State University Press.
Stewart, H. T. L., Hopmans, P., & Flinn, D. W. (1990). Establishment and early growth of trees irrigated with waste water at four sites in Victoria, Australia. Forest Ecology and Management, 25, 233–269.
Tye, A. M., Young, S. D., Crout, N. M. J., Zhang, H., Preston, S., Barbosa-Jefferson, V. L., Davison, W., McGrath, S. P., Paton, G. I., Kilham, K., & Resende, L. (2003). Geochimical Acta, 67, 375–385.
Walkely, A., & Black, I. A. (1934). An examination of the Degtijzreff method for determining soil organic matter and a proposed modification of the chromic acid titration method. Soil Science, 37, 29–38.
Wiger, Q., Hamedi, J., Marwal, R. P., Singh, B. R., & Kuhad, M. S. (2004). Heavy metal accumulation and mobility in soils affected by irrigating agricultural crops with sewage water. In A. L. Juhasz, G. Magesan, & R. R. Naidu (Eds.), Waste management (pp. 81–96). Enfield: Science publishers, Inc.
Yadav, R. K., Goyal, B., Sharma, R. K., Dubey, K., & Minhas, P. S. (2002). Post irrigation impact of domestic sewage effluent on composition of soils, crops and ground water—a case study. Environment International, 28(6), 481–486.
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Deshmukh, S.K., Singh, A.K. & Datta, S.P. Impact of wastewater irrigation on the dynamics of metal concentrations in the vadose zone: monitoring: part I. Environ Monit Assess 187, 695 (2015). https://doi.org/10.1007/s10661-015-4898-3
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DOI: https://doi.org/10.1007/s10661-015-4898-3